A power storage module including: a stacked body that includes electrodes stacked along a first direction; a sealing body that includes a first sealing portion joined to an edge portion of each of the electrodes, forms an inner space between the electrodes adjacent to each other, and seals the inner space; and an electrolytic solution that is stored in the inner space and includes an alkali solution. The electrodes include bipolar electrodes, and a negative terminal electrode. The power storage module includes surplus spaces different from the inner space on a route of an alkali creep phenomenon in which the electrolytic solution reaches the outside from the inner space through the negative terminal electrode.

A conventional bipolar battery is constituted of a combination of cells hermetically sealed for preventing a liquid junction and preventing corrosion of a peripheral device due to a liquid leakage. Therefore, electrolytic solution injecting processes are carried out as many as the number of cells, so that much times and costs have been required for manufacturing a large-scale battery. In addition, a wiring space has been required since the cells are connected to one another with wires. The use of a current collector formed of a one-end closed tubular conductor, the current collector having a bottom protruding outward to form a protrusion, eliminates the wiring space and achieves a reduction in ohmic loss due to the wires. In addition, an electrolytic solution in one cell is separated by a water-repellent sheet from an electrolytic solution in another cell, so that a liquid junction is prevented.

Elements of an electrochemical cell using an end to end process. The method includes depositing a planarization layer, which manufactures embedded conductors of said cell, allowing a deposited termination of optimized electrical performance and energy density. The present invention covers the technique of embedding the conductors and active layers in a planarized matrix of PML or other material, cutting them into discrete batteries, etching the planarization material to expose the current collectors and terminating them in a post vacuum deposition step.

Various embodiments of the present technology comprise a method and apparatus for a battery. According to various embodiments, the battery comprises a layered structure comprising a current collector, an active material, and a non-electrically conductive permeable layer. The layered structure is repeated with a separator disposed between adjacent layered structures.

A bipolar battery having at least two electrochemical cells electrically arranged in series includes a housing, an electrolyte, a bipolar electrode, an anode, a cathode, and first and second microporous separators. The bipolar electrode comprises a first anode material and a first cathode material. The first cathode and anode materials are disposed on opposite faces of a current collector. The anode comprises a second anode material comprising: a zinc compound, a zinc oxide compound, and a binder, and the cathode comprises a second cathode material comprising: a manganese oxide, a conductive carbon, and a copper compound. The first cathode material faces the second anode material, and the first anode material faces the second cathode material. The first microporous separator is disposed between the first cathode material and the second anode material, and the second microporous separator is disposed between the first anode material and the second cathode material.

A conventional bipolar battery is constituted of a combination of cells hermetically sealed for preventing a liquid junction and preventing corrosion of a peripheral device due to a liquid leakage. Therefore, electrolytic solution injecting processes are carried out as many as the number of cells, so that much times and costs have been required for manufacturing a large-scale battery. In addition, a wiring space has been required since the cells are connected to one another with wires. The use of a current collector formed of a one-end closed tubular conductor, the current collector having a bottom protruding outward to form a protrusion, eliminates the wiring space and achieves a reduction in ohmic loss due to the wires. In addition, an electrolytic solution in one cell is separated by a water-repellent sheet from an electrolytic solution in another cell, so that a liquid junction is prevented.

Each of plurality of unit cells includes a current collecting plate including a first main surface and a second main surface that are arranged in a stacking direction of the plurality of unit cells. The unit battery includes a separator impregnated with an electrolytic solution, the unit battery being disposed on the first main surface, a seal member provided on the first main surface, the seal member surrounding a periphery of the unit battery, and the seal member being in tight contact with the current collecting plates adjacent to the seal member in the stacking direction by a pressing force from the fastening tool.

Provided are bipolar batteries that include a stacked plurality of cells. Two or more of the cells include a cathode, an anode, a proton or hydroxide ion conducting polymer separator between the cathode and said anode, wherein in some aspects the separator includes or alone acts as a proton or hydroxide conducting electrolyte, and a bipolar metallic plate associated with the anode or the cathode. The cells optionally include and electrolyte that includes a polymer capable of conducting a proton or a hydroxide ion. The separator may in the form of a film and is optionally not bonded to either the anode or the cathode, or may be in the form of a coating on the anode, the cathode, or any combination thereof.

Elements of an electrochemical cell using an end to end process. The method includes depositing a planarization layer, which manufactures embedded conductors of said cell, allowing a deposited termination of optimized electrical performance and energy density. The present invention covers the technique of embedding the conductors and active layers in a planarized matrix of PML or other material, cutting them into discrete batteries, etching the planarization material to expose the current collectors and terminating them in a post vacuum deposition step.

The invention provides for a fully electrically rechargeable metal anode battery systems and methods of achieving such systems. An electrically rechargeable metal anode cell may comprise a metal electrode, an air contacting electrode, and an aqueous electrolyte separating the metal electrode and the air contacting electrode. In some embodiments, the metal electrode may directly contact the liquid electrolyte and no separator or porous membrane is needed between the air contacting electrode and the electrolyte. Rechargeable metal anode cells may be electrically connected to one another through a centrode connection where a metal electrode of one cell and an air contacting electrode of a second cell are electrically connected. Air tunnels or pathways may be provided between individual metal anode cells arranged in a stack. In some embodiments, an electrolyte flow management system may also be provided to maintain liquid electrolyte at constant levels during charge and discharge cycles.